A Rutherford backscattering study on radiation damage and the diffusion of krypton implanted into 6H-SiC
A pebble bed modular reactor (PBMR) is a modern type high-temperature gas-cooled nuclear reactor (HTGR). The fuels of the PBMR are in the form of small multi-layered spheres called triple-coated isotropic (TRISO) particles. A key feature of this PBMR technology is the entrapment of the fission pr...
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Language: | en |
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University of Pretoria
2015
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Online Access: | http://hdl.handle.net/2263/46049 Mabena, CM 2014, A Rutherford backscattering study on radiation damage and the diffusion of krypton implanted into 6H-SiC, MSc Dissertation, University of Pretoria, Pretoria, viewed yymmdd <http://hdl.handle.net/2263/46049> |
Summary: | A pebble bed modular reactor (PBMR) is a modern type high-temperature gas-cooled
nuclear reactor (HTGR). The fuels of the PBMR are in the form of small
multi-layered spheres called triple-coated isotropic (TRISO) particles. A key feature
of this PBMR technology is the entrapment of the fission products (FPs) within the
TRISO particles. Silicon carbide (SiC) is used as the main layer in the TRISO
particles. Given the sophistication of the TRISO design the release of silver (Ag) has
motivated a thorough investigation concerning the ability of SiC to entrap other
fission products. In this project volume diffusion of Kr in 6H-SiC was investigated
under the influence of radiation damage.
Kr (360 keV) ions were implanted into 6H-SiC at three different temperatures, i.e.
room temperature, 350 oC and 600 oC, up to a fluence of 2×1016 ions/cm2. The
radiation damage retained after implantation was assessed with the Rutherford
backscattering technique in the channelling mode (RBS-C). Annealing of radiation
damage and diffusion of the implanted Kr were investigated during isochronal
annealing in the temperature range 1000 – 1500 oC in steps of 100 oC for 5 hours
using RBS-C and Rutherford backscattering spectroscopy (RBS), respectively.
The room temperature implantation amorphised the 6H-SiC to a depth of
approximately 280 nm from the surface. This occurred because the thermal energy of
the atoms at this temperature was not high enough to allow the displaced atoms to recombine with their designated lattice positions. The high temperature implantations
did not amorphise the 6H-SiC. The implantation at these temperatures did, however,
cause a distortion of the 6H-SiC because of the defects and/or defect clusters that
were retained. The 350 oC implantation retained a high damage density as compared
to the 600 oC implantation. The reason for the decrease in damage density with
increasing temperature can be explained in terms of the thermal energy available for
the atoms to move around in the SiC. A high temperature implies a higher mobility of
the atoms thus increasing the probability of the displaced atoms to recombine with
their designated lattice positions. Consequently, a slight diffusion of the Kr was also
observed at the high temperature implantations relative to the room temperature
implantation. The Kr depth profiles were broader for the high temperature
implantation. Implantation at different temperatures caused different degrees of
retained radiation damage in the SiC, consequently, isochronal annealing was done to
assess the recovery of the SiC and also the diffusion of the implanted Kr inside the
SiC under the different conditions.
Epitaxial re-crystallisation from the amorphous-crystalline interface was observed
after annealing the room temperature implanted sample at 1000 oC. However, no
change in the Kr depth profile was observed after annealing at 1000 and 1100 oC for
5 hours. Annealing the same sample from 1100 to 1300 oC in steps of 100 oC for
5 hours did not result in any further epitaxial re-crystallisation. There, however, was a
slight change of the SiC from the surface region at 1200 oC. The Kr depth profile
started to broaden slightly at 1200 oC. An increased broadening was further observed
at 1300 oC. In both instances the Kr depth profiles maintained an approximately
Gaussian shape. This change in the Kr depth profile implies that there was Fickian
type diffusion of the Kr at these temperatures. Annealing at 1400 oC resulted in a loss
of about 30% of the Kr accompanied by a shift of the Kr depth profile towards the
surface. These changes occurred simultaneously with the major epitaxial
re-crystallisation of the SiC from the amorphous-crystalline interface. Further
annealing at 1500 oC caused an additional loss of about 20% of the Kr accompanied
by a pronounced shift towards the surface. This also occurred concurrently with the
remarkable re-crystallization of the SiC. The Kr depth profile changes that occurred at
1400 and 1500 oC resulted in an asymmetric Kr profile and thus cannot be explained
in terms of the Fickian diffusion process. The observed abrupt changes at 1400 and 1500 oC are consistent with the influence of thermal etching. This is because the
thermal etching effect could have influenced the RBS spectrum and resulted in
asymmetric depth profiles due the surface inhomogeneity.
Unlike in the room temperature implantation case where the thermal energy had to be
enough to allow (1) excess defects to escape the disordered region; (2) provide
sufficient mobility to allow atomic re-ordering, and finally (3) allow for the formation
of appropriate bonds, in the high temperature case there was a consistent decrease in
the retained damage with each annealing cycle. Through-out the annealing cycles the
350 oC implantation retained more damage than the 600 oC implantation. In all the
annealing instances there was no observable change in the Kr depth profiles implying
that no diffusion took place despite the re-ordering of the displaced host atoms. The
stability of the Kr atoms in their implanted positions is a possible contributor to the
resistance of the SiC from returning to its virgin crystalline structure as observed
through the RBS-C spectrum. This is because the Kr atoms exist as point defects in
the SiC lattice thus causing the de-channelling of the He ions as they penetrate the
SiC. This, in addition to the de-channelling from the extended defects, caused an
increased backscattering spectrum from the host atoms. Thorough-out the entire
isochronal annealing experiments in the temperature range 1000 – 1500 oC the
6H-SiC retained all of the implanted Kr. === Dissertation (MSc)--University of Pretoria, 2014. === tm2015 === Physics === MSc === Unrestricted |
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